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HS Code |
793050 |
| Product Name | 2-(Difluoromethoxy)-5-Bromopyridine |
| Cas Number | 1227578-77-3 |
| Molecular Formula | C6H4BrF2NO |
| Molecular Weight | 224.00 |
| Appearance | Colorless to pale yellow liquid |
| Purity | Typically ≥98% |
| Density | 1.750 g/cm³ |
| Boiling Point | 220-223 °C (estimated) |
| Refractive Index | n20/D 1.545 (estimated) |
| Smiles | C1=CN=C(C=C1Br)OC(F)F |
| Inchi | InChI=1S/C6H4BrF2NO/c7-4-1-2-10-3-5(4)11-6(8)9 |
| Solubility | Soluble in organic solvents (e.g., DMSO, dichloromethane) |
| Storage Condition | Store at 2-8°C, tightly closed |
| Synonyms | 5-Bromo-2-(difluoromethoxy)pyridine |
As an accredited 2-(Difluoromethoxy)-5-Bromopyridine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
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People in pharmaceutical research know that new ideas often depend on having the right ingredients at hand — both for reliable synthesis and for advancing creative projects. 2-(Difluoromethoxy)-5-Bromopyridine stands out as a chemical that’s earned trust among scientists for versatile applications. Its formula, C6H4BrF2NO, brings together a bromine and a difluoromethoxy group on the pyridine ring, but the impact goes much further than a formula might suggest.
This compound appears as a pale to colorless liquid or sometimes a low-melting solid, depending on the batch and storage. Its structure holds up well under a range of lab conditions. Unlike many halogenated pyridines that quickly darken or break down under exposure, 2-(Difluoromethoxy)-5-Bromopyridine keeps its integrity for extended periods with standard storage away from heat and light. This kind of stability makes it easier for scientists to rely on consistent results, reducing unnecessary repeat runs and wasted resources.
Pyridine rings are classic in medicinal chemistry, thanks to their strong binding profiles and role as drug “scaffolds.” Adding a difluoromethoxy group changes electronic properties and metabolic fate, which opens up pathways for targeted drug design. The bromo substituent, located at the 5-position, works as a handle for cross-coupling — Suzuki, Buchwald–Hartwig, or Sonogashira — so laboratories can quickly build more complex molecules. In practical synthesis, I’ve found this lets teams save days or even weeks in multi-step scaffolding for small molecule drug candidates.
Medicinal chemists appreciate how 2-(Difluoromethoxy)-5-Bromopyridine allows for easier incorporation of fluorine into lead compounds. The difluoromethoxy group tweaks metabolic stability and boosts the likelihood that a molecule passes critical ADME (absorption, distribution, metabolism, excretion) tests. In my experience, swapping a methoxy or ethoxy group for a difluoromethoxy often makes a difference in how compounds handle oxidative stress — a big deal in lead optimization cycles.
Beyond drug-making, agrochemical researchers have turned to compounds like this to dial in potency on pest targets while keeping environmental profiles cleaner than old-generation halogenated chemicals. The diverse substitution pattern lets R&D teams compare analogs side-by-side, identifying versions with lower soil persistence or reduced off-target activity. These little tweaks pave the way for safer and more efficient solutions in crop protection.
Chemists hate surprises, especially where small impurities or isomers sneak in. A product like this matters because of the high purity you can expect from reputable producers. Analytical data from GC-MS and NMR show clear and predictable spectra, so synthetic teams can start their work without troubleshooting unexpected side peaks or inconsistent results. That means clear documentation and cleaner regulatory submissions for both pharmaceutical and agrochemical projects.
I’ve worked on multi-kilo campaigns where a single unexpected trace impurity can hold up months of work. Sourcing reliable 2-(Difluoromethoxy)-5-Bromopyridine can sidestep those project stalls and keep internal quality assurance satisfied, freeing up attention for creative breakthroughs rather than damage control.
A decade ago, fluorinated pyridines involved tough, fiddly chemistry and exotic reagents that made scale-up a major headache. Advances have streamlined how products like 2-(Difluoromethoxy)-5-Bromopyridine come to market. Fewer side-products, easier handling, lower environmental risks: these benefits mark real progress over older, less predictable pyridine derivatives.
Many classic bromo-pyridines lack the electron-shifting effects that a difluoromethoxy brings to a molecule. This can mean a higher degree of control over both intermolecular interactions and reactivity during follow-up transformations. Those subtle differences translate into more selective reactions, cleaner purifications, and greater flexibility for late-stage functionalization.
Labs face mounting pressure to improve efficiency and shrink their environmental footprint. Modern synthesis leans away from stubborn solvents and dangerous intermediates, and the latest generations of 2-(Difluoromethoxy)-5-Bromopyridine fit neatly into these improved workflows. Reproducible preparation and thoughtful packaging mean both less hazardous waste and smoother compliance with health and safety regulations.
Handling is straightforward with proper ventilation, gloves, and eye protection. I’ve seen teams train junior chemists to use this compound with confidence, helping build skills while reducing lab accident rates. Its relatively low volatility compared to lighter pyridine analogues also means less chemical loss from evaporation or air exposure, which helps keep experiments running on-target.
Timing carries real weight in research planning. Delays with key intermediates can mean missed grant deadlines or slowdowns in competitive development pipelines. Over the years, being able to acquire 2-(Difluoromethoxy)-5-Bromopyridine as a high-purity, ready-to-use reagent has removed headaches for project managers and purchasing teams. Reliable supply chains and good shelf stability give an edge to groups racing to make new chemical space accessible.
In collaborative environments, where academic and industrial labs often work hand-in-hand, having a common foundation of well-characterized building blocks speeds up knowledge sharing. Joint projects can proceed without long negotiations about sample purity, stability, or reproducibility. The reduced friction means breakthroughs move from concept to result with fewer unnecessary stops along the way.
Shifting from bench-scale experiments to multi-gram or kilo quantities often uncovers new challenges — mixing, heat transfer, or unexpected reactivity at larger volumes. 2-(Difluoromethoxy)-5-Bromopyridine tends to behave consistently across batch sizes. Consistent melting points, low volatility, and predictable solubility in common solvents (THF, acetonitrile, dichloromethane) relieve many operational worries. As someone who’s overseen scale-ups, I appreciate how minimizing surprises with intermediates cuts costs and time spent troubleshooting.
Technicians and engineers, not just PhDs, need to feel confident handling and storing specialty reagents. This compound’s relative ease of handling and compatible safety profile keeps teams moving and helps satisfy environmental health and safety audits. Smaller container options reduce risks associated with large-volume transfers, an often-overlooked but critical consideration in busy pilot plants or kilo labs.
Training junior scientists remains one of the most rewarding parts of my role. The combination of functional handles on this molecule (both bromine and difluoromethoxy) gives newcomers hands-on exposure to multiple reactivity pathways. It’s more than a teaching tool; it grants access to coupling reactions, nucleophilic substitutions, and late-stage fluorination — all using a single substrate. That kind of versatility is valuable when laying the groundwork for emerging scientists to build their practical expertise.
Universities and start-ups with tight budgets benefit, too. Stepping beyond simple starting materials toward more advanced building blocks opens doors to real-world reactions and ideas. Buying or using 2-(Difluoromethoxy)-5-Bromopyridine isn’t just about saving steps — it’s about demystifying tricky transformations and encouraging bolder synthetic plans.
Adjacent pyridine derivatives often miss the combined power delivered by bromine and a difluoromethoxy group. Simple 5-bromopyridines lack fluorine’s contributions to metabolic tuning; plain difluoromethoxy pyridines leave behind the cross-coupling handle. In hands-on lab work, this dual capability unlocks overnight routes to diverse analog libraries, enabling exploratory studies across bigger sections of chemical space. Even compared to fancier or more exotic fluorinated pyridines, 2-(Difluoromethoxy)-5-Bromopyridine offers a practical sweet spot for both cost and performance.
Quality and transparency matter more than ever, especially with increased scrutiny on laboratory sourcing and research reproducibility. Trust in a product like 2-(Difluoromethoxy)-5-Bromopyridine comes from validated production routes and documented quality assessments. Leading suppliers back up their offerings with batch-specific NMR and GC-MS traces, giving end-users the confidence to pursue even the toughest synthetic targets.
My own work in collaborative research consortia highlighted how clean, well-defined intermediates foster both scientific and regulatory confidence. Everyone benefits: compliance officers can verify composition against regulatory standards; chemists reduce troubleshooting; teams avoid misattribution of unexpected results. This kind of reliability keeps projects moving forward, even as external expectations continue to rise.
As the boundaries of molecular discovery stretch ever farther, the molecules that help make that future possible deserve recognition. 2-(Difluoromethoxy)-5-Bromopyridine fits into a larger picture of improved research tools — tools that reflect a commitment to both quality and innovation. Ongoing support for verified sourcing, responsible handling practices, and open communication between producers and end-users will keep these building blocks reliable.
Sustainability efforts across chemistry now shape what gets made and how it gets made. Process chemists and R&D managers look for materials with improved profiles, both for regulatory ease and long-term feasibility. I’ve watched this compound gain favor thanks to improved availability and a real focus on minimizing associated hazards. Producers have listened to researchers’ concerns, adjusting processes to cut problematic waste and lower the risk of handling byproducts.
An innovation-driven culture calls for the right mix of predictability and creative possibility. With 2-(Difluoromethoxy)-5-Bromopyridine, chemists gain the freedom to take bigger steps and aim higher with new molecular targets. Whether the goal is a breakthrough therapeutic or a safer agricultural compound, easy access to well-characterized building blocks shortens the path between questions and answers.
Many of the most meaningful lab advances I’ve witnessed happened when teams felt empowered to try techniques once thought slow, risky, or too uncertain to pursue. Having the right materials on hand didn’t solve every challenge — but it did remove friction at critical moments, so attention and energy flowed into discovery, not damage control.
Demand for fluorinated motifs in small-molecule synthesis shows no signs of slowing down. New methods combining classic transition-metal catalysis with modern ligands put fresh spin on what chemists can achieve. In those workflows, reliable intermediates like 2-(Difluoromethoxy)-5-Bromopyridine mean less downtime, faster iteration, and fewer headaches about reproducibility.
Some research teams focus on finding fast, modular solutions to current bottlenecks; others tackle grand challenges like greener synthesis or more accessible medicine. In each scenario, the value of robust, multipurpose reagents cannot be overstated. Convenience, versatility, and trust take pressure off teams navigating tight timelines and high stakes.
Every reagent comes with challenges. 2-(Difluoromethoxy)-5-Bromopyridine remains a specialty item, not as ubiquitous as simple pyridine derivatives or commodity halides. Price and sourcing, especially for larger campaigns, call for careful supplier vetting and logistics coordination. For regions lacking direct supplier access, partners must weigh import timelines and costs against the payoff of more efficient chemistry.
As fluorinated compounds attract closer regulatory scrutiny, labs should stay proactive on safety, waste handling, and documentation. Routine training and clear protocols reduce incidents and support sustainability policies. Manufacturers have stepped up by making safety data, transportation advice, and storage recommendations clearer and more user-friendly, which helps keep both personnel and the surrounding environment as safe as possible.
Improvements in recycling fluoro-containing waste streams and advances in greener halogenation methods signal real promise on the sustainability front. Teams that keep pace with these developments will be better positioned to meet regulatory and ethical expectations.
Science progresses faster when everyone can tap into the same high-quality materials. Scaling up production and improving transportation options broadens the pool of potential users, helping universities and start-ups step onto the same stage as larger industrial players. Regular auditing, open supplier communication, and participation in global quality initiatives will continue to raise the bar for all.
People who care about accessibility recognize that quality assurance isn’t a luxury — it’s the bedrock of trustworthy science. Each unit of 2-(Difluoromethoxy)-5-Bromopyridine purchased and used according to validated standards carries forward that ethos. It’s a compound whose thoughtful production and proven reliability enable researchers to move further, faster, and with greater certainty.
New research tools rarely make headlines, yet the unsung intermediates shape the success of drug candidates, crop protection agents, and all the creative chemistry in between. 2-(Difluoromethoxy)-5-Bromopyridine delivers tangible advantages in reactivity, reliability, and forward-thinking handling. Its role as a trusted reagent within the scientific community grows as more researchers demand sustainable, efficient, and innovative solutions. The smallest ingredients can make the biggest impact — not always on the cover of journals, but in the everyday practice of world-changing chemistry.
